Engine stop control device

ABSTRACT

Target rotation speed at a reference point, which is set at a top dead center (TDC) preceding a target stop position of engine rotation by a predetermined crank angle, is set. A target trajectory of an engine rotation behavior extending since an engine rotation stop behavior starts until the target rotation speed at the reference point is reached is calculated based on the target rotation speed at the reference point and an engine friction. Torque of an alternator (electric machinery) is controlled to conform the engine rotation behavior to the target trajectory during the engine rotation stop behavior. The target rotation speed at the reference point is set to rotation speed that is equal to or lower than lower limit rotation speed of a rotation speed range, where the torque of the alternator is generated, and that is close to the lower limit rotation speed.

CROSS REFERENCE TO RELATED APPLICATION

This application is based on and incorporates herein by reference Japanese Patent Application No. 2008-205949 filed on Aug. 8, 2008.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an engine stop control device having a function to control an engine rotation stop position (stop crank angle) when an engine stops.

2. Description of Related Art

In recent years, as described in Patent document 1 (JP-A-2005-315202), there has been a vehicle mounted with an engine automatic stop-start system (idle stop system) that performs control for increasing a target current value of an alternator to an initial value set at a large value beforehand and then decreasing the target current value when an engine is stopped automatically, aiming to control an engine rotation stop position (stop crank angle) into a crank angle range, which is suitable for start, during engine stop (idle stop) and to improve restarting performance.

An engine stop control device described in above Patent document 1 controls the engine rotation stop position into the target crank angle range by controlling a load of the alternator when automatically stopping the engine. However, practically, the control device merely sets the target current value of the alternator in accordance with present engine rotation speed with the use of a preset map when the engine rotation speed, which is sensed when a piston passes a compression top dead center (TDC), is in a range from 480 rpm to 540 rpm (refer to paragraph 69 of Patent document 1). Therefore, the control of the alternator load is rough and it is difficult to sufficiently compensate a variation in an engine rotation behavior during an engine stop process. Therefore, it is thought that the control device of Patent document 1 cannot reduce the variation in the engine rotation stop position sufficiently and cannot exert a sufficient effect to improve the restarting performance.

In order to solve the problem, the applicant of the present application filed patent applications of an invention for calculating a target engine rotation behavior (referred to as target trajectory, hereinafter) extending until engine rotation stops at a target stop position and for controlling an accessory load of an engine to conform an engine rotation behavior to the target trajectory as described in specifications of Japanese Patent Applications No. 2007-53598 and No. 2007-54775.

In the engine stop process, cylinder pressure changes with compression and expansion of cylinder air caused by rotation of the engine. The cylinder pressure at the engine rotation stop changes in accordance with a crank angle at the engine rotation stop and therefore compression torque (torque caused by cylinder pressure) acting on a crankshaft changes. Accordingly, the target trajectory suitable for stopping the engine rotation at the target stop position also changes. In the invention of the above applications, such the change in the target trajectory is not taken into account. Therefore, accuracy of the target trajectory worsens correspondingly.

In order to solve such the problem, the applicant of the present application filed an application of an invention for correcting the target trajectory in accordance with the target stop position in consideration of an influence of the compression as described in a specification of Japanese Patent Application No. 2007-325520. According to the invention, the target trajectory can be set accurately when there is no error. However, a characteristic of a friction or compression governing the engine rotation stop behavior changes due to oil temperature, oil degradation, aging change and the like. Therefore, in order to accurately set the target trajectory, it is necessary to learn the friction and the compression from a stop position error separately. However, it is difficult to learn the compression and the friction from the stop position error separately.

SUMMARY OF THE INVENTION

The present invention has been made in consideration of the above circumstances. Therefore, it is an object of the present invention to provide an engine stop control device capable of accurately setting a target trajectory of an engine rotation stop behavior and of accurately controlling an engine rotation stop position to a target stop position.

In order to achieve the above object, according to a first aspect of the present invention, an engine stop control device that performs engine stop control for controlling an engine rotation behavior with torque of an electric machinery such that an engine rotation stop position is controlled to a target stop position when the control device stops engine rotation in response to an engine stop request has a reference point target rotation speed setting section, a target trajectory calculating section, and a stop controlling section. The reference point target rotation speed setting section sets target rotation speed at a reference point, which is set at a point preceding the target stop position by a predetermined crank angle. The target trajectory calculating section calculates a target trajectory of the engine rotation behavior extending since the engine stop control is started until the target rotation speed at the reference point is reached based on the target rotation speed at the reference point and an engine friction. The stop controlling section controls the torque of the electric machinery to conform the engine rotation behavior to the target trajectory during execution of the engine stop control.

An influence of compression arises in a very low rotation range immediately before the engine rotation stops. Therefore, by setting the target trajectory extending to the target rotation speed at the reference point that is set at the point preceding the target stop position by the predetermined crank angle as in the present invention, the target trajectory can be set in the range preceding the very low rotation range where the influence of the compression arises. Thus, the engine rotation behavior can be accurately conformed to the target trajectory by the electric machinery during the engine rotation stop behavior without being affected by the compression. Thus, the actual rotation speed can be accurately conformed to the target rotation speed at the reference point. The target rotation speed at the reference point is set to the engine rotation speed at the reference point necessary for stopping the engine rotation at the target stop position from the reference point. That is, the setting is made such that the target stop position is located on an extended line of the target trajectory extending to the reference point. Therefore, as the actual rotation speed can be accurately conformed to the target rotation speed at the reference point by the present invention, the actual stop position of the engine rotation can be conformed to the target stop position with high accuracy.

In this case, according to a second aspect of the present invention, the target rotation speed at the reference point is set to or under lower limit rotation speed of a rotation speed range, in which the torque of the electric machinery is generated. With such the construction, the influence of the torque of the electric machinery does not appear in the engine rotation behavior from the reference point to the target stop position. Accordingly, the error in the stop position due to the torque of the electric machinery can be eliminated and the accuracy of the stop position can be improved.

There is a case where a characteristic of the engine friction changes in accordance with the crank argle to the reference point due to multiple accessories of the internal combustion engine and the like in the process since the engine rotation stop behavior starts until the target rotation speed at the reference point is reached. In consideration of such the case, according to a third aspect of the present invention, the target trajectory is calculated by selecting the engine friction from the multiple engine frictions in accordance with the crank angle to the reference point. With such the construction, the engine friction used for the calculation of the target trajectory can be changed in response to the phenomenon that the characteristic of the engine friction changes in accordance with the crank angle to the reference point due to the multiple accessories of the internal combustion engine and the like in the process since the engine rotation stop behavior starts until the target rotation speed at the reference point is reached. Accordingly, the accuracy of the target trajectory can be improved.

According to a fourth aspect of the present invention, the engine stop control device further has a learning correction performing section for performing learning correction of the target rotation speed at the reference point based on a difference between an actual stop position and the target stop position of the engine rotation (i.e., error in stop position). Since the setting is made such that the target stop position is located on the extended line of the target trajectory extending to the reference point, it is thought that the error in the stop position is caused by the error in the target rotation speed at the reference point (error in target trajectory). Therefore, the accuracy of the target rotation speed at the reference point can be improved by performing the learning correction of the target rotation speed at the reference point based on the error in the stop position.

BRIEF DESCRIPTION OF THE DRAWINGS

Features and advantages of an embodiment will be appreciated, as well as methods of operation and the function of the related parts, from a study of the following detailed description, the appended claims, and the drawings, all of which form a part of this application. In the drawings:

FIG. 1 is a schematic construction diagram of an entire engine control system according to an embodiment of the present invention.

FIG. 2 is a diagram illustrating a setting method of a target trajectory.

FIG. 3 is a flowchart illustrating a processing flow of a time synchronization routine.

FIG. 4 is a flowchart illustrating a processing flow of a crank angle synchronization routine.

FIG. 5 is a flowchart illustrating a processing flow of an engine stop request determination routine.

FIG. 6 is a flowchart illustrating a processing flow of an engine start request determination routine.

FIG. 7 is a flowchart illustrating a processing flow of a first engine stop control routine.

FIG. 8 is a flowchart illustrating a processing flow of a reference point learning routine.

FIG. 9 is a flowchart illustrating a processing flow of a friction learning routine.

FIG. 10 is a flowchart illustrating a processing flow of a second engine stop control routine.

FIG. 11 is a flowchart illustrating a processing flow of a stop position control routine.

FIG. 12 is a flowchart illustrating a processing flow of a first engine start control routine.

FIG. 13 is a diagram showing an example of a first ignition cylinder map.

FIG. 14 is a flowchart illustrating a processing flow of a second engine start control routine.

FIG. 15 is a time chart showing an example of engine stop control according to the embodiment.

FIG. 16 is a diagram showing an example of a norm Ne² error upper limit and lower limit map.

FIG. 17 is a diagram showing an example of a map of a lower limit value ThAltMin of a controllable energy deviation.

FIG. 18 is a diagram showing an example of a map of an upper limit value ThAltMax of the controllable energy deviation.

FIG. 19 is a time chart showing an example of a behavior of engine rotation speed Ne at the time when a first ignition cylinder causes normal combustion.

FIG. 20 is a time chart showing an example of a behavior of the engine rotation speed Ne at the time when the first ignition cylinder causes a misfire.

FIG. 21 is a time chart showing behaviors of a sensing value and an actual value of the engine rotation speed Ne and a sensing value of a crank angle immediately after a fuel cut (or in initial stage of engine stop behavior).

FIG. 22 is a diagram illustrating a method for calculating feedback correction torque Tfb such that a deviation (energy deviation) between target Ne² and actual Ne² becomes zero at a position preceding a reference point by a predetermined crank angle [(4π/N)×β].

DETAILED DESCRIPTION OF EXAMPLE EMBODIMENT

Hereinafter, an embodiment embodying the best mode for implementing the present invention will be described.

First, a schematic construction of entirety of an engine control system will be explained with reference to FIG. 1.

An air cleaner 13 is arranged in the most upstream portion of an intake pipe 12 of an internal combustion engine 11. An airflow meter 14 sensing intake air quantity is provided downstream of the air cleaner 13. A throttle valve 16, whose opening degree is regulated by a motor 15, and a throttle position sensor 17 sensing the opening degree of the throttle valve 16 (throttle opening) are provided downstream of the airflow meter 14. A surge tank 18 is provided downstream of the throttle valve 16. An intake manifold 20 that introduces air into each cylinder of the engine 11 is connected to the surge tank 18. An injector 21 that injects fuel is provided near an intake port of the intake manifold 20 of each cylinder. A spark plug 22 is provided to a cylinder head of the engine 11 for each cylinder. A mixture gas in the cylinder is ignited by a spark discharge of the spark plug 22.

An exhaust gas sensor 24 (air-fuel ratio sensor, oxygen sensor or the like) that senses an air-fuel ratio or a rich/lean state of exhaust gas is provided to an exhaust pipe 23 of the engine 11. A catalyst 25 such as a three-way catalyst that purifies the exhaust gas is provided downstream of the exhaust gas sensor 24.

A coolant temperature sensor 26 that senses coolant temperature is provided to a cylinder block of the engine 11. A signal rotor 29 having teeth on its outer periphery at a predetermined crank angle pitch is fitted to a crankshaft 27 of the engine 11. A crank angle sensor 28 is provided to be opposed to the outer periphery of the signal rotor 29. Every time the tooth of the signal rotor 29 faces the crank angle sensor 28 (i.e., every time crankshaft 27 rotates by predetermined crank angle), the crank angle sensor 28 outputs a crank pulse signal. Engine rotation speed is sensed based on a cycle of the output pulse of the crank angle sensor 28 (or pulse output frequency). A cam angle sensor (not shown) that outputs a cam pulse signal at a predetermined cam angle in synchronization with rotation of a camshaft of the engine 11 is provided.

Rotation of the crankshaft 27 is transmitted to an alternator 33 as a typical accessory of the engine 11 through a belt transmission mechanism (not shown). Thus, the alternator 33 is rotated and driven by the power of the engine 11 to generate electricity. Torque of the alternator 33 can be controlled by duty control of a power generation control current (field current) of the alternator 33. In the present embodiment, the alternator 33 is used as an electric machinery described in the claims.

Outputs of the above various sensors are inputted to an engine control circuit 30 (hereafter, referred to as ECU). The ECU 30 is constituted mainly by a microcomputer and controls fuel injection quantity and injection timing of the injector 21 and ignition timing of the spark plug 22 in accordance with an engine operation state sensed with the various sensors. When a predetermined automatic stop condition is established and an engine stop request (idle stop request) is generated during an idle operation, the ECU 30 performs an idle stop to stop combustion (ignition and/or fuel injection) and to stop the engine rotation. When a driver performs an operation for starting a vehicle while the engine is stopped by the idle stop, a predetermined automatic start condition is established and the ECU 30 energizes a starter (not shown) to crank and automatically start the engine 11.

The ECU 30 executes routines shown in FIGS. 3 to 14 explained later. Thus, the ECU 30 functions as a reference point target rotation speed setting section, a target trajectory calculating section, and a stop controlling section. The reference point target rotation speed setting section sets target rotation speed at a reference point, which is set at a top dead center (TDC) preceding a target stop position (target stop crank angle) of the engine rotation by a predetermined crank angle. The target trajectory calculating section calculates a target trajectory of an engine rotation behavior extending since the engine stop control is started until the target rotation speed at the reference point is reached based on the target rotation speed at the reference point and an engine friction. The stop controlling section controls the torque of the alternator 33 to conform the engine rotation behavior to the target trajectory during execution of the engine stop control.

The target rotation speed at the reference point, which is set at the TDC preceding the target stop position of the engine rotation by the predetermined crank angle, is set at rotation speed that is equal to or lower than lower limit rotation speed of a rotation speed range, in which the torque of the alternator 33 is generated, and that is close to the lower limit rotation speed. More specifically, the target rotation speed at the reference point is set such that the engine rotation speed between the reference point and the TDC immediately preceding the reference point becomes equal to or lower than the lower limit rotation speed of the torque generation rotation speed range of the alternator 33. With such the setting, in an interval since the engine rotation stop behavior starts until the vicinity of the target rotation speed at the reference point is reached, control can be performed to conform the engine rotation behavior to the target trajectory using the torque of the alternator 33. In addition, the torque of the alternator 33 does not affect the engine rotation behavior from the reference point to the target stop position. Thus, an error in the stop position due to the torque of the alternator 33 can be eliminated.

The target trajectory is defined by calculating target engine rotation speeds for respective TDCs in the interval since the engine rotation stop behavior starts until the target rotation speed at the reference point is reached and by allotting the calculated target engine rotation speeds in a table (refer to FIG. 2).

During an engine stop process, a kinetic energy (rotation energy) is attenuated by the engine friction and the engine rotation speed decreases. Therefore, the actual engine rotation speed can be conformed to the target rotation speed at the reference point with high accuracy by calculating the target trajectory based on the engine friction and the target rotation speed at the reference point and by controlling the torque of the alternator 33 to conform the actual engine rotation behavior to the target trajectory. Moreover, the torque of the alternator 33 does not affect the engine rotation behavior in the interval from the reference point to the target stop position. Therefore, the error of the stop position due to the torque of the alternator 33 can be eliminated. As a result, the actual stop position of the engine rotation can be conformed to the target stop position with high accuracy.

In the process since the engine rotation stop behavior starts until the target rotation speed at the reference point is reached, a characteristic of the engine friction changes in accordance with the crank angle to the reference point because of the multiple accessories of the engine 11 and the like. In consideration of this point, in the present embodiment, the target trajectory is calculated by selecting the engine friction from the multiple engine frictions in accordance with the crank angle to the reference point. In the example of FIG. 2, the engine friction set in an interval from the reference point to M1 is different from the engine friction set in an interval from M1 to M.

The above-described engine stop control according to the present embodiment is performed by the ECU 30 according to the respective routines of FIGS. 3 to 14. Next, processing contents of the respective routines will be explained.

[Time Synchronization Routine]

A time synchronization routine shown in FIG. 3 is performed by the ECU 30 repeatedly in a predetermined cycle (e.g., 8 ms cycle) while a power source of the ECU 30 is ON (i.e., while a power source of an ignition switch is ON). If the routine is started, first in step 100, an engine stop request determination routine shown in FIG. 5 explained later is executed to determine whether an engine stop request (idle stop request) is generated.

Then, the process proceeds to step 200, in which an engine start request determination routine shown in FIG. 6 explained later is executed to determine whether an engine start request (automatic start request after idle stop) is generated.

Then, the process proceeds to step 300, in which a first engine stop control routine shown in FIG. 7 explained later is executed to calculate request torque of the alternator 33 (hereafter, referred to as request alternator torque). Then, in following step 400, a first engine start control routine shown in FIG. 12 explained later is executed to set a first ignition cylinder and a second ignition cylinder in the automatic start.

[Crank Angle Synchronization Routine]

A crank angle synchronization routine shown in FIG. 4 is executed by the ECU 30 repeatedly at every predetermined crank angle (e.g., at every 30 deg CA) while the power source of the ECU 30 is ON (i.e., while the power source of the ignition switch is ON). If the routine is started, first in step 500, a second engine start control routine shown in FIG. 14 explained later is executed to perform fuel injection control, ignition control and misfire determination of the first ignition cylinder in the automatic start.

Then, the process proceeds to step 550, in which it is determined whether present time is TDC timing as execution timing of stop position control. If the present time is not the TDC timing, the routine is ended as it is. If the present time is the TDC timing, the process proceeds to step 600, in which a second engine stop control routine shown in FIG. 10 explained later is executed to perform the stop position control.

[Engine Stop Request Determination Routine]

The engine stop request determination routine shown in FIG. 5 is a subroutine executed in step 100 of the time synchronization routine of FIG. 3. If the routine is started, first in step 101, it is determined whether an automatic stop condition (idle stop execution condition) is established.

In the case of a manual transmission vehicle, the automatic stop condition is established when either one of following conditions (a), (b) is satisfied.

(a) A shift position is in a forward gear range, vehicle speed is equal to or lower than a predetermined value (for example, equal to or lower than 10 km/h), a brake pedal is pressed (brake=ON), and a clutch is disengaged (clutch pedal is pressed).

(b) A shift position is in a neutral range and a clutch is engaged (clutch pedal is not pressed).

In the case of an automatic transmission vehicle (AT vehicle), the automatic stop condition is established when either one of following conditions (c), (d) is satisfied.

(c) A shift position is in a forward gear range or in a neutral range, vehicle speed is equal to or lower than a predetermined value (for example, equal to or lower than 10 km/h), and a brake pedal is pressed (brake=ON).

(d) A shift position is in a parking range.

If it is determined that the automatic stop condition is not established in step 101, the routine is ended as it is. If it is determined that the automatic stop condition is established in step 101, the process proceeds to step 102, in which the engine stop request is outputted (ON) and the routine is ended.

[Engine Start Request Determination Routine]

The engine start request determination routine shown in FIG. 6 is a subroutine executed in step 200 of the time synchronization routine of FIG. 3. If the routine is started, first in step 201, it is determined whether the automatic start condition is established (i.e., whether driver has performed operation for starting vehicle).

In the case of a manual transmission vehicle, it is determined that the driver has performed the operation for starting the vehicle and the automatic start condition is established when either one of following conditions (a), (b) is satisfied.

(a) A shift position is in a forward gear range and a brake operation is cancelled (brake=OFF) or a clutch is engaged (clutch pedal is not pressed).

(b) A shift position is in a neutral range and a clutch is disengaged (clutch pedal is pressed).

In the case of an automatic transmission vehicle (AT vehicle), it is determined that the driver has performed the operation for starting the vehicle and the automatic start condition is established when a following condition (c) is established.

(c) A shift position is in other range than a parking range and a brake operation is cancelled (brake=OFF).

When it is determined that the automatic start condition is not established in step 201, the routine is ended as it is. When it is determined that the automatic start condition is established in step 201, the process proceeds to step 202, in which it is determined whether the shift position is in a neutral range or a clutch is disengaged (clutch pedal is pressed). If the automatic start is performed when the shift position is not in the neutral range and also the clutch is not disengaged, the power of the engine 11 is transmitted to driving wheels and the vehicle starts moving on its own. Therefore, in this case, the routine is ended without outputting the engine start request.

When it is determined in step 202 that the shift position is in the neutral range or the clutch is disengaged (clutch pedal is pressed), the power transmission from the engine 11 to the driving wheels is blocked and the vehicle maintains the stopped state even if the automatic start is performed. Therefore, in this case, the process proceeds to step 203, in which the engine start request is outputted, and the routine is ended.

[First Engine Stop Control Routine]

The first engine stop control routine shown in FIG. 7 is a subroutine performed in step 300 of the time synchronization routine of FIG. 3. If the routine is started, first in step 301, it is determined whether an engine stop request is outputted based on the processing result of the engine stop request determination routine of FIG. 5. When the engine stop request is not outputted, the routine is ended as it is without performing subsequent processing.

If it is determined in step 301 that the engine stop request is outputted, the process proceeds to step 302, in which it is determined whether a fuel cut flag is set at ON. The fuel cut flag is set in step 304 mentioned later. When the fuel cut flag is set at ON, it indicates that fuel cut is in execution. When the fuel cut flag is not set at ON, the process proceeds to step 303, in which it is determined whether present engine rotation speed Ne is higher than a predetermined value Ne1. In accordance with the determination result, processing of steps 304 to 306 or processing of steps 307 to 309 is performed. If the engine rotation speed Ne at the start of the engine stop control is too low, the number of the TDCs until the reference point is reached becomes too small and it becomes difficult to conform the engine rotation behavior to the target trajectory. Therefore, the processing of steps 304 to 306 and the processing of steps 307 to 309 are provided to control the engine rotation speed Ne at the start of the engine stop control to or over the predetermined value Ne1 necessary for conforming the engine rotation behavior to the target trajectory.

If it is determined in step 303 that the present engine rotation speed Ne is higher than the predetermined value Ne1, it is determined that the engine rotation speed Ne necessary for conforming the engine rotation behavior to the target trajectory is secured. In this case, the process proceeds to step 304, in which the fuel cut flag is set at ON to perform the fuel cut. In following step 305, the throttle opening is increased to a first predetermined value Ta1 (i.e., opening larger than idle speed control opening). In following step 306, the request alternator torque is set by adding offset torque Tofs, which is reference torque of the torque control of the alternator 33, and feedback correction torque Tfb, which is used for performing feedback correction of an error between the actual engine rotation behavior and the target trajectory.

Request alternator torque=Tofs+Tfb

For example, the offset torque Tofs is set at a half of maximum controllable torque of the alternator 33. The alternator 33 cannot output assist torque unlike a motor generator, but the torque of the alternator 33 can be controlled in both of positive and negative directions in a virtual manner. That is, the torque of the alternator 33 can be controlled by regarding the torque smaller than the offset torque Tofs as virtual negative torque and regarding the torque larger than the offset torque Tofs as virtual positive torque. Thus, performance of the engine rotation behavior to follow the target trajectory can be improved.

The offset torque Tofs is not limited to the half of the maximum torque. Alternatively, the offset torque Tofs may be ⅓, ¼, ⅔, ¾ or the like of the maximum torque. Arbitrary torque that is smaller than the maximum controllable torque of the alternator 33 and larger than zero may be set as the offset torque Tofs.

0<Tofs<maximum torque

If it is determined in step 302 that the fuel cut flag has been already set at ON, the processing of steps 303 to 305 is skipped and the processing of step 306 is executed.

If it is determined in step 303 that the present engine rotation speed Ne is equal to or lower than the predetermined value Ne1, the process proceeds to step 307, in which the ignition timing is advanced to a certain value or a knock limit. Thus, the engine torque is increased and the engine rotation speed Ne is increased. In following step 308, a compressor OFF request is outputted (i.e., compressor OFF flag is switched on) to switch off a compressor of an air conditioner. Thus, a load on the engine 11 is reduced and the engine rotation speed Ne is increased. Alternatively, the engine rotation speed may be increased by increasing the intake air quantity (i.e., increasing throttle opening) or increasing the fuel injection quantity. Then, the process proceeds to step 309, in which request alternator torque is restricted to the offset torque Tofs.

Request alternator torque=Tofs

In following step 310, it is determined whether a throttle opening is requested (i.e., whether TDC immediately before stop position has been passed). If the throttle opening is requested, the process proceeds to step 311, in which the throttle opening is set to a second predetermined value Ta2 larger than the first predetermined value Ta1. If it is determined in step 310 that there is no throttle opening request, the processing in step 311 is not executed and the throttle opening is continuously maintained at the first predetermined value Ta1.

Then, the process proceeds to step 312, in which it is determined whether a predetermined time has elapsed after the engine rotation speed Ne lowers to speed equal to or lower than rotation speed Ne2 immediately preceding the engine stop. As shown in FIG. 15, the rotation speed Ne2 immediately before the stop corresponds to rotation speed at time immediately after the TDC, which is immediately before the stop position. The predetermined time is set to time for waiting until the engine rotation surely stops.

If it is determined in step 312 that the predetermined time has not elapsed after the engine rotation speed Ne lowers to speed equal to or lower than the rotation speed Ne2 immediately preceding the stop, the routine is ended as it is. Thereafter, if step 312 is determined to be “Yes” when the predetermined time elapses after the engine rotation speed Ne lowers to speed equal to or lower than the rotation speed Ne2 immediately preceding the stop, the process proceeds to step 313. In step 313, a reference point learning routine of FIG. 8 explained later is executed to calculate target Ne at a next reference point. Ne means the rotation speed, hereinafter. Then, the process proceeds to step 314, in which a friction learning routine of FIG. 9 explained later is executed to learn first and second frictions Tfr1, Tfr2 of the engine 11.

[Reference Point Learning Routine]

The reference point learning routine shown in FIG. 8 is a subroutine executed in step 313 of the first engine stop control routine shown in FIG. 7 and functions as a learning correction performing means of the claims. If the routine is started, first in step 321, a stop position error is calculated by a following formula.

Stop position error=(actual stop position crank angle−current reference point crank angle)mod 720+{(720/N)×K−target stop position crank angle}

(Actual stop position crank angle−current reference point crank angle) mod 720 means a remainder crank angle provided when (actual stop position crank angle−current reference point crank angle) is divided by 720 [deg CA]. For example, when (actual stop position crank angle −current reference point crank angle) is 1000 [deg CA], (1000) mod 720=280 [deg CA].

When (actual stop position crank angle −current reference point crank angle) is 400 [deg CA], (400) mod 720=400 [deg CA]. In the above formula, N represents the cylinder number of the engine 11 and K represents the number of the TDCs having passed from the current reference point to the actual stop position.

Then, the process proceeds to step 322, in which an upper limit and a lower limit of a norm Ne² error corresponding to the stop position error are calculated with reference to a norm Ne² error upper limit and lower limit map shown in FIG. 16.

Norm Ne² error upper limit=norm Ne² error upper limit map (stop position error)

Norm Ne² error lower limit=norm Ne² error lower limit map (stop position error)

The norm Ne² error upper limit and lower limit map shown in FIG. 16 is set such that the upper limit and the lower limit of the norm Ne² error increase as the stop position error increases.

Then, the process proceeds to step 323, in which upper limit and lower limit of a next reference point target Ne base value are calculated by following formulae.

Next reference point target Ne base value upper limit=√{square root over ( )}(current reference point actual Ne ²−Norm Ne ² error lower limit)

Next reference point target Ne base value lower limit=√{square root over ( )}(current reference point actual Ne ²−Norm Ne ² error upper limit)

Then, the process proceeds to step 324, in which the next reference point target Ne base value lower limit is compared with the current reference point target Ne. If the next reference point target Ne base value lower limit is larger than the current reference point target Ne, the process proceeds to step 326, in which the next reference point target Ne base value lower limit is used as the next reference point target Ne base value.

Next reference point target Ne base value=next reference point target Ne Base Value Lower Limit

If it is determined in step 324 that the next reference point target Ne base value lower limit is equal to or smaller than the current reference point target Ne, the process proceeds to step 325. In step 325, the next reference point target Ne base value upper limit is compared with the current reference point target Ne. If the next reference point target Ne base value upper limit is smaller than the current reference point target Ne, the process proceeds to step 327, in which the next reference point target Ne base value upper limit is used as the next reference point target Ne base value.

Next reference point target Ne base value=next reference point target Ne base value upper limit

If the determination result is “NO” in both of steps 324 and 325, i.e., if the current reference point target Ne exists between the lower limit and the upper limit of the next reference point target Ne base value, the process proceeds to step 328. In step 328, the current reference point target Ne is continuously used as the next reference point target Ne base value.

Next reference point target Ne base value=current reference point target Ne

Thus, the next reference point target Ne base value is set in either one of steps 326 to 328. Then, the process proceeds to step 329, in which the next reference point target Ne is obtained by smoothing processing based on a following formula.

Next reference point target Ne=current reference point target Ne−γ*(current reference point target Ne−next reference point target Ne base value)

In the above formula, γ is a smoothing coefficient (0<y≦1).

[Friction Learning Routine]

The friction learning routine shown in FIG. 9 is a subroutine executed in step 314 of the first engine stop control shown in FIG. 7. If the routine is started, first in step 330, it is determined whether a friction learning execution condition is established based on whether a stop position control mode (explained later)=1 (i.e., feedback correction torque Tfb=0). If the friction learning execution condition is not established, the routine is ended without performing subsequent processing.

If it is determined that the friction learning execution condition is established in step 330, the process proceeds to step 331. In step 331, trajectory data (x_(n), y_(n)) of the actual rotation behavior in the interval (0 to M₁) in which the first friction (Tfr1) is calculated are read.

x _(n)={0, 720/N, . . . ,(720/N)×M ₁}

y_(n)={reference point actual Ne², actual Ne² at the time when m=1, . . . , actual Ne² at the time when m=M₁}

x_(n) is a crank angle from the reference point to each TDC (0 to M₁) in the interval where the first friction is calculated (refer to FIG. 2). y_(n) is actual Ne² at each TDC in the interval of the first friction. N is the cylinder number of the engine 11, and M₁ is a starting point of the interval of the first friction (i.e., the number of TDCs from reference point).

Then, the process proceeds to step 332, in which a first inclination is calculated by a least-square method.

$\begin{matrix} {{{First}\mspace{14mu} {inclination}} = \frac{{n{\sum\limits_{k = 1}^{n}{x_{k}y_{k}}}} - {\sum\limits_{k = 1}^{n}{x_{k}{\sum\limits_{k = 1}^{n}y_{k}}}}}{{n{\sum\limits_{k = 1}^{n}x_{k}^{2}}} - \left( {\sum\limits_{k = 1}^{n}x_{k}} \right)^{2}}} & \left\lbrack {{Expression}\mspace{14mu} 1} \right\rbrack \end{matrix}$

In the above formula, n=M₁+1.

Then, the process proceeds to step 333, in which the first friction (Tfr1) is calculated by a following formula using the first inclination.

Tfr1=(π·I/10)×first inclination

In the formula, I represents an engine inertia moment [kgm].

Then, the process proceeds to step 334. In step 334, trajectory data (x_(n), y_(n)) of the actual rotation behavior in the interval (M₁ to M) in which the second friction (Tfr2) is calculated are read.

x _(n)={0, 720/N, . . . , (720/N)×(M−M ₁)}

y _(n)={actual Ne ² at M ₁, actual Ne ² at the time when m=M ₁+1, . . . , actual Ne ² at the time when m=M}

x_(n) is a crank angle at each TDC (M₁ to M) in the interval, in which the second friction is calculated (refer to FIG. 2). y_(n) is the actual Ne² at each TDC in the interval of the second friction.

Then, the process proceeds to step 335, in which a second inclination is calculated by a least square method. Then, the process proceeds to step 336, in which the second friction (Tfr2) is calculated by a following formula using the second inclination.

Tfr2=(π·I/10)×second inclination

When there are three or more frictions, processing for calculating the inclination by the above-described least square method and for calculating the friction may be repeated.

Alternatively, the function to learn the friction (friction learning routine) may be omitted. The present invention may be implemented by calculating the friction based on experiment data, design date and the like and by storing the friction in a nonvolatile memory such as ROM of the ECU 30 beforehand.

[Second Engine Stop Control Routine]

The second engine stop control routine shown in FIG. 10 is a subroutine executed in step 600 of the crank angle synchronization routine shown in FIG. 4. If the routine is started, first in step 601, the target Ne is calculated as follows.

First, target Ne² [M] in the interval (0 to M₁) of the first friction (Tfr1) and the interval (M₁ to M) of the second friction (Tfr2) is calculated by a following formula.

Target Ne ² [M]={10/(π·I)}×[0, 720Tfr1/N, (720Tfr1/N)×2, . . . , (720Tfr1/N)×M ₁, (720Tfr2/N)×(M ₁+1), . . . , (720Tfr2/N)×(M−1)]+reference point target Ne ²

Generally, because of the principle of energy conservation, a following relationship is established between the engine inertia moment I and the friction Tfr.

(½)·I·ω ² =Tfr·θ

ω is angular speed [rad/s] and ⊖ is a rotational angle [rad].

ω=(2π/60)·Ne

⊖=(π/180)·θ

θ: rotational angle [deg]

A following formula is derived from the above relationship.

Ne ²=(10/π·I)·Tfr·θ

The target Ne² [M] is calculated using the above relationship.

After the target Ne² [M] is calculated, “m” that satisfies a following expression is obtained (0≦m≦M).

Target Ne ² [m]−(target Ne ² [m]−target Ne ² [m−1])(1−α)≦actual Ne ²<target Ne ² [m]+(target Ne ² [m+1]−target Ne ² [m])α

In the above expression, 0≦α≦1. “m” satisfying the above expression represents the position of the TDC, at which the control is performed currently (i.e., m-th TDC from reference point).

Then, the current target Ne is calculated from the target Ne² at the m-th TDC from the reference point by a following formula.

Target Ne=√{square root over ( )}target Ne²

Thus, as the actual Ne decreases, values of the target Ne at the respective TDCs are serially calculated based on the frictions Tfr1, Tfr2 and the reference point target Ne. Thus, the target trajectory is set.

After the current target Ne is calculated as above, the process proceeds to step 602, in which it is determined whether a stop position control execution condition is established, for example, based on whether both of following conditions (a), (b) are satisfied.

(a) The number of the TDCs after the fuel cut is equal to or larger than a predetermined value (for example, two).

(b) 1<m<another predetermined value (for example, 15).

“m” is the TDC number to the reference point.

The above condition (a) is used for following reason. That is, as shown in FIG. 21, decrease width ΔNe of the engine rotation speed Ne becomes smaller than an actual value due to the smoothing processing of the engine rotation speed Ne, which is sensed from the output pulse of the crank angle sensor 28, immediately after the fuel cut (i.e., in initial stage of engine stop behavior). Accordingly, the friction is estimated to be smaller than an actual value.

The above condition (b) is used because there is no need to start the stop position control from the TDC that is far from the reference point beyond necessity. In addition, it is difficult to perform the stop position control when the engine rotation speed is too high.

The stop position control execution condition is not established and the stop position control is not performed if at least either one of the conditions (a), (b) is not satisfied.

If both of the conditions (a), (b) are satisfied, the stop position control execution condition is established and the process proceeds to step 603, in which a stop position control routine shown in FIG. 11 explained later is executed to calculate the feedback correction torque Tfb of the request alternator torque.

Then, the process proceeds to step 604, in which it is determined whether the reference point is reached (i.e., whether previous m=1). If the reference point is not reached, the routine is ended as it is. If the reference point is reached, the process proceeds to step 605, in which the throttle opening request is outputted. Thus, the throttle opening is increased to the second predetermined value Ta2 larger than the first predetermined value Ta1.

Arbitrary throttle opening timing may be used as long as the opening timing is synchronized with the TDC. Therefore, it may be determined in step 604 whether previous m=2 (or 3, for example) and the throttle opening request may be outputted when the previous m=2 (or 3, for example). It suffices if the throttle opening is increased at the reference point or at the TDC slightly preceding the reference point.

[Stop Position Control Routine]

The stop position control routine shown in FIG. 11 is a subroutine executed in step 603 of the second engine stop control routine shown in FIG. 10. If the routine is started, first in step 611, it is determined whether a stop position control mode has been determined. If the stop position control mode has been determined, the routine is ended without performing subsequent processing.

If the stop position control mode has not been determined yet, the process proceeds to step 612, in which it is determined whether a deviation (energy deviation) between the target Ne² and the actual Ne² is smaller than a lower limit value ThAltMin at the m-th TDC, at which the control is performed currently, with reference to a map of the lower limit value ThAltMin of the controllable energy deviation shown in FIG. 17. If it is determined that the deviation between the target Ne² and the actual Ne² is smaller than the lower limit value ThAltMin, the process proceeds to step 613, in which the stop position control mode is set to “3.” In following step 614, the feedback correction torque Tfb of the request alternator torque is set to a minimum value (for example, −8).

If it is determined in step 612 that the deviation between the target Ne² and the actual Ne² is equal to or larger than the lower limit value ThAltMin, the process proceeds to step 615, in which it is determined whether the deviation between the target Ne² and the actual Ne² is larger than an upper limit value ThAltMax at the m-th TDC, at which the control is performed currently, with reference to a map of the upper limit value ThAltMax of the controllable energy deviation shown in FIG. 18. If it is determined that the deviation between the target Ne² and the actual Ne² is larger than the upper limit value ThAltMax, the process proceeds to step 616, in which the stop position control mode is set to “2.” Then, in following step 617, the feedback correction torque Tfb of the request alternator torque is set to a maximum value (for example, 10).

If it is determined in step 615 that the deviation between the target Ne² and the actual Ne² is equal to or smaller than the upper limit value ThAltMax, the process proceeds to step 618, in which it is determined whether an absolute value of the deviation between the target Ne² and the actual Ne² (i.e., |target Ne²−actual Ne²|) is smaller than a determination value (for example, 5000). When the absolute value |target Ne²−actual Ne²| is smaller than the determination value, the deviation between the target Ne² and the actual Ne² is small. Therefore, in this case, it is determined that there is no need to perform the feedback control of the torque of the alternator 33 and the process proceeds to step 619, in which the stop position control mode is set to “1.” Then, in following step 620, the feedback correction torque Tfb of the request alternator torque is set to 0. Thus, the first and second frictions (Tfr1, Tfr2) can be learned in a state where the torque of the alternator 33 is fixed at the offset torque Tofs (i.e., in a state where feedback control is prohibited) over an entire range of the engine rotation stop behavior.

If it is determined in step 618 that |target Ne²−actual Ne²| is equal to or larger than the determination value, it is determined that the present state is in the feedback control range, and the process proceeds to step 621, in which the stop position control mode is set to “0.” Then, in following step 622, the feedback correction torque Tfb of the request alternator torque is calculated by a following formula.

Tfb=(½)×I×(2π/60)²×(actual Ne ²−target Ne ²)÷{(4π/N)×(m−1−β)}

In the above formula, β represents an adjustment parameter for calculating the crank angle from the reference point to a position where the generation of the torque of the alternator 33 ceases (0≦β≦1).

As shown in FIG. 22, the generation of the torque of the alternator 33 ceases at a position preceding the reference point by a predetermined crank angle [(4π/N)×β]. Therefore, the feedback correction torque Tfb is calculated such that the deviation (energy deviation) between the target Ne² and the actual Ne² becomes zero at the position preceding the reference point by the predetermined crank angle [(4π/N)×β] with the use of the above formula. In this case, the position preceding the reference point by the predetermined crank angle [(4π/N)×β] is set at a position where the actual Ne coincides with the lower limit rotation speed of the torque generation rotation speed range of the alternator 33. Alternatively, the position may be set at a position where the actual Ne becomes rotation speed slightly higher than the lower limit rotation speed of the torque generation rotation speed range of the alternator 33.

The stop position control mode is determined based on the deviation (energy deviation) between the target Ne² and the actual Ne² at the start of the stop position control by the processing of the above-described stop position control routine. Based on the determination result, the feedback correction torque Tfb of the request alternator torque is set as follows.

(A) When the deviation between the target Ne² and the actual Ne² is smaller than the lower limit value ThAltMin of the controllable energy deviation, the stop position control mode is set to “3” and the feedback correction torque Tfb of the request alternator torque is set to the minimum value (for example, −8).

(B) When the deviation between the target Ne² and the actual Ne² is larger than the upper limit value ThAltMax of the controllable energy deviation, the stop position control mode is set to “2” and the feedback correction torque Tfb of the request alternator torque is set to the maximum value (for example, 10).

By fixing the feedback correction torque Tfb of the request alternator torque at the maximum value or the minimum value when the deviation between the target Ne² and the actual Ne² exceeds the upper limit value or the lower limit value of the controllable energy deviation as in above (A) or (B), the control can be performed also in a range where the control cannot be performed by the feedback control.

(C) When |target Nee²−actual Ne²| is smaller than the determination value, the deviation between the target Ne² and the actual Ne² is small. Therefore, in this case, it is determined that the feedback control of the torque of the alternator 33 is unnecessary. In this case, the stop position control mode is set to “1” and the feedback correction torque Tfb of the request alternator torque is set to 0. Thus, the first and second frictions (Tfr1, Tfr2) can be learned in a state where the feedback control of the torque of the alternator 33 is prohibited over the entire range of engine rotation stop behavior.

(D) In the other case than the above, it is determined that the present state is in the feedback control range. In this case, the stop position control mode is set to “0” and the feedback correction torque Tfb of the request alternator torque is calculated.

[First Engine Start Control Routine]

The first engine start control routine shown in FIG. 12 is a subroutine executed in step 400 of the time synchronization routine shown in FIG. 3. If the routine is started, first in step 401, it is determined whether the engine start is requested based on the processing result of the engine start request determination routine of FIG. 6. If the engine start is not requested, the routine is ended as it is.

If the engine start is requested, the process proceeds to step 402, in which it is determined whether the first ignition cylinder for performing the ignition first in the automatic start has not been set. If the first ignition cylinder has been already set, the routine is ended without performing subsequent processing.

If it is determined that the first ignition cylinder has not been set yet, the process proceeds to step 403, in which a temporary first ignition cylinder corresponding to the crank angle of the stop position is set with reference to a first ignition cylinder map shown in FIG. 13 (in the case of four-cylinder engine). In the present embodiment, the stop position can be controlled to the target stop position with high accuracy. Therefore, the crank angle of the target stop position may be used as the crank angle of the stop position. Then, the process proceeds to step 404. In step 404, a cylinder, in which the TDC is reached next to the temporary first ignition cylinder, is set as a temporary second ignition cylinder.

Then, the process proceeds to step 405, in which it is determined whether a misfire time number Nmf of the temporary first ignition cylinder sensed by a second engine start control routine of FIG. 14 explained later is larger than a first ignition prohibition threshold value. If the misfire time number Nmf of the temporary first ignition cylinder is larger than the first ignition prohibition threshold value, the process proceeds to step 406, in which the temporary second ignition cylinder is set as the first ignition cylinder and a cylinder, in which the TDC is reached next to the temporary second ignition cylinder, is set as the second ignition cylinder.

If it is determined in step 405 that the misfire time number Nmf of the temporary first ignition cylinder is equal to or smaller than the first ignition prohibition threshold value, the process proceeds to step 407, in which the temporary first ignition cylinder is set as the first ignition cylinder as it is and the temporary second ignition cylinder is set as the second ignition cylinder as it is.

[Second Engine Start Control Routine]

The second engine start control routine shown in FIG. 14 is a subroutine executed in step 500 of the crank angle synchronization routine shown in FIG. 4. If the routine is started, first in step 501, it is determined whether the engine start is requested based on the processing result of the engine start request determination routine of FIG. 6. If the engine start is not requested, the routine is ended as it is.

If the engine start is requested, the process proceeds to step 502, in which fuel injection control is performed. In following step 503, ignition control is performed.

Then, the process proceeds to step 504, in which it is determined whether the present time is the TDC timing. If the present time is not the TDC timing, the routine is ended as it is. If the present time is the TDC timing, the process proceeds to step 505, in which it is determined whether the present time is the TDC timing of the first ignition cylinder. If the present time is the TDC timing of the first ignition cylinder, the process proceeds to step 506, in which the actual Ne at the TDC timing of the first ignition cylinder is stored as Nef in the memory of the ECU 30 (RAM or the like).

If it is determined in step 505 that the present time is not the TDC timing of the first ignition cylinder, the process proceeds to step 507, in which it is determined whether the present time is TDC timing of the second ignition cylinder. If the present time is not the TDC timing of the second ignition cylinder, the routine is ended as it is.

Thereafter, when the TDC timing of the second ignition cylinder is reached, the process proceeds to step 508, in which it is determined whether a deviation ΔNe (=actual Ne−Nef) between the actual Ne at the TDC timing of the second ignition cylinder and the rotation speed Nef at the TDC timing of the first ignition cylinder stored in the memory is “equal to or smaller than” a misfire determination threshold value. Thus, it is determined whether the first ignition cylinder has caused the misfire.

If the normal combustion occurs in the first ignition cylinder, the actual Ne increases suddenly and the deviation ΔNe between the actual Ne at the TDC timing of the second ignition cylinder and the actual Ne (=Nef) at the TDC timing of the first ignition cylinder increases as shown in FIG. 19. If the misfire occurs in the first ignition cylinder the actual Ne does not increase significantly as shown in FIG. 20. Therefore, the deviation ΔNe between the actual Ne at the TDC timing of the second ignition cylinder and the actual Ne (=Nef) at the TDC timing of the first ignition cylinder is much smaller than in the case of the normal combustion. Based on such the characteristic, when the deviation ΔNe is equal to or smaller than the misfire determination threshold value, it is determined that the first ignition cylinder has caused a misfire and the process proceeds to step 509. In step 509, a misfire time number counter that counts the misfire time number Nmf of the first ignition cylinder is incremented. The misfire time number counter is provided for each cylinder. For each cylinder, the misfire time number counter of the cylinder counts the misfire time number Nmf at the time when the cylinder is the first ignition cylinder. If the deviation ΔNe is larger than the misfire determination threshold value, it is determined that the first ignition cylinder has caused the normal combustion.

FIG. 15 is a time chart showing an example of the engine stop control according to the present embodiment described above. In the control example, when the engine stop request is outputted (ON), the engine rotation speed Ne is lower than the predetermined value Ne1 necessary for conforming the engine rotation behavior to the target trajectory. Therefore, the ignition timing is advanced to increase the engine torque, and the compressor OFF flag is set at ON to stop the compressor and to reduce the load on the engine 11. Thus, the engine rotation speed Ne is increased.

In this way, when the engine rotation speed Ne exceeds the predetermined value Ne1, the fuel cut flag is set at ON to perform the fuel cut, and the throttle opening is increased from the idle speed control opening to the first predetermined value Ta1. Thereafter, when the stop position control execution condition is established, the stop position control is started and the request alternator torque is set based on the offset torque Tofs and the feedback correction torque Tfb.

Request alternator torque=Tofs+Tfb

The request alternator torque is set at the offset torque Tofs when the engine stop request is outputted (ON).

Thereafter, the request alternator torque becomes zero when the establishment of the stop position control execution condition fails. Further, the throttle opening is increased from the first predetermined value Ta1 to the second predetermined value Ta2 when the reference point is reached. Thereafter, when a predetermined time elapses after the engine rotation speed Ne decreases to or under the rotation speed Ne2 immediately preceding the stop, the next reference point target Ne is learned based on the stop position error and the frictions Tfr1, Tfr2 are learned.

The influence of the compression arises in a very low rotation range immediately before the engine rotation stops. Therefore, in the present embodiment, the target trajectory (target Ne at respective TDCs) extending to the target Ne at the reference point, which is set at the position preceding the target stop position by a predetermined crank angle, is set. Thus, the target trajectory can be set in the range preceding the very low rotation range in which the influence of the compression arises. Thus, the engine rotation behavior can be accurately conformed to the target trajectory by the alternator 33 during the engine rotation stop behavior without being affected by the compression. Thus, the actual Ne can be conformed to the target Ne with high accuracy at the reference point. The target Ne at the reference point is set to the engine rotation speed at the reference point necessary for stopping the engine rotation at the target stop position from the reference point. That is, the setting is made such that the target stop position is located on an extended line of the target trajectory extending to the reference point. Therefore, as the actual Ne can be accurately conformed to the target Ne at the reference point by the control according to the present embodiment, the actual stop position of the engine rotation can be conformed to the target stop position with high accuracy.

According to the present embodiment, the target Ne at the reference point is set to be equal to or lower than the lower limit rotation speed of the rotation speed range in which the torque of the alternator 33 is generated. Thus, the influence of the torque of the alternator 33 does not appear in the engine rotation behavior extending from the reference point to the target stop position. As a result, the error in the stop position due to the torque of the alternator 33 can be eliminated and the accuracy of the stop position can be improved.

In the process since the engine rotation stop behavior starts until the target Ne at the reference point is reached, a characteristic of the engine friction changes in accordance with the crank angle (TDC number) to the reference point because of the multiple accessories of the engine 11 and the like. In consideration of this point, in the present embodiment, the target trajectory is calculated by selecting the engine friction from the multiple engine frictions in accordance with the crank angle (TDC number) to the reference point. Therefore, the engine friction used for the calculation of the target trajectory can be changed in response to the phenomenon that the characteristic of the engine friction changes in accordance with the crank angle (TDC number) to the reference point because of the multiple accessories of the engine 11 and the like in the process since the engine rotation stop behavior starts until the target Ne at the reference point is reached. Thus, the accuracy of the target trajectory can be improved.

The setting is made such that the target stop position is located on the extended line of the target trajectory extending to the reference point. Therefore, it is thought that the error in the stop position is caused by the error in the target Ne at the reference point (error in target trajectory). In consideration of this point, in the present embodiment, the target Ne at the reference point is learned and corrected based on the error in the stop position. Accordingly, the accuracy of the target Ne at the reference point can be improved.

In the engine stop process, cylinder pressure of each cylinder operates in a direction to hinder the engine rotation (i.e., direction in which kinetic energy decreases) in a compression stroke and operates in a direction to help the engine rotation (i.e., direction in which kinetic energy increases) in an expansion stroke. Therefore, balance of the kinetic energy due to the cylinder pressure becomes zero for each TDC. Paying attention to this point, according to the present embodiment, the target trajectory is set for each TDC. Therefore, the target trajectory can be set with high accuracy by eliminating the influence of cyclic change of the kinetic energy due to the cylinder pressure, and the calculation for setting the target trajectory can be simplified.

The present invention is not limited to the construction that sets the target trajectory for each TDC. Alternatively, the target trajectory may be set for each predetermined crank angle interval.

In the present embodiment, the torque of the alternator 33 is controlled during the engine stop control. Alternatively, other electric machinery than the alternator 33 (e.g., motor generator of hybrid vehicle) may be controlled.

While the invention has been described in connection with what is presently considered to be the most practical and preferred embodiments, it is to be understood that the invention is not to be limited to the disclosed embodiments, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. 

1. An engine stop control device that performs engine stop control for controlling an engine rotation behavior with torque of an electric machinery such that an engine rotation stop position is controlled to a target stop position when the control device stops engine rotation in response to an engine stop request, the control device comprising: a reference point target rotation speed setting means for setting target rotation speed at a reference point, which is set at a point preceding the target stop position by a predetermined crank angle; a target trajectory calculating means for calculating a target trajectory of the engine rotation behavior extending since the engine stop control is started until the target rotation speed at the reference point is reached based on, the target rotation speed at the reference point and an engine friction; and a stop controlling means for controlling the torque of the electric machinery to conform the engine rotation behavior to the target trajectory during execution of the engine stop control.
 2. The engine stop control device as in claim 1, wherein the reference point target rotation speed setting means sets the target rotation speed at the reference point to or under lower limit rotation speed of a rotation speed range, in which the torque of the electric machinery is generated.
 3. The engine stop control device as in claim 1, wherein the target trajectory calculating means calculates the target trajectory by selecting the engine friction from the multiple engine frictions in accordance with a crank angle to the reference point.
 4. The engine stop control device as in claim 1, further comprising: a learning correction performing means for performing learning correction of the target rotation speed at the reference point based on a difference between an actual stop position and the target stop position of the engine rotation. 